Calculus/Finite Limits

Now, we will try to more carefully restate the ideas of the last chapter. We said then that the equation limx→2f(x)=4{\displaystyle \lim _{x\to 2}f(x)=4} meant that, when x{\displaystyle x} gets close to 2, f(x){\displaystyle f(x)} gets close to 4. What exactly does this mean? How close is "close"? The first way we can approach the problem is to say that, at x=1.99,f(x)=3.9601{\displaystyle x=1.99\ ,\ f(x)=3.9601} , which is pretty close to 4.

Sometimes however, the function might do something completely different. For instance, suppose f(x)=x4−2x2−3.77{\displaystyle f(x)=x^{4}-2x^{2}-3.77} , so f(1.99)=3.99219201{\displaystyle f(1.99)=3.99219201} . Next, if you take a value even closer to 2, f(1.999)=4.20602{\displaystyle f(1.999)=4.20602} , in this case you actually move further from 4. The reason for this is that substitution gives us 4.23 as x{\displaystyle x} approaches 2.

The solution is to find out what happens arbitrarily close to the point. In particular, we want to say that, no matter how close we want the function to get to 4, if we make x{\displaystyle x} close enough to 2 then it will get there. In this case, we will write

Sometimes, it is necessary to consider what happens when we approach an x{\displaystyle x} value from one particular direction. To account for this, we have one-sided limits. In a left-handed limit, x{\displaystyle x} approaches a{\displaystyle a} from the left-hand side. Likewise, in a right-handed limit, x{\displaystyle x} approaches a{\displaystyle a} from the right-hand side.

For example, if we consider limx→2x−2{\displaystyle \lim _{x\to 2}{\sqrt {x-2}}} , there is a problem because there is no way for x{\displaystyle x} to approach 2 from the left hand side (the function is undefined here). But, if x{\displaystyle x} approaches 2 only from the right-hand side, we want to say that x−2{\displaystyle {\sqrt {x-2}}} approaches 0.

Definition: (Informal definition of a one-sided limit)

We call L{\displaystyle L} the limit of f(x){\displaystyle f(x)} as x{\displaystyle x} approaches c{\displaystyle c} from the right if f(x){\displaystyle f(x)} becomes arbitrarily close to L{\displaystyle L}wheneverx{\displaystyle x} is sufficiently close to and greater thanc{\displaystyle c} .

When this holds we write

limx→c+f(x)=L{\displaystyle \lim _{x\to c^{+}}f(x)=L}

Similarly, we call L{\displaystyle L} the limit of f(x){\displaystyle f(x)} as x{\displaystyle x} approaches c{\displaystyle c} from the left if f(x){\displaystyle f(x)} becomes arbitrarily close to L{\displaystyle L}wheneverx{\displaystyle x} is sufficiently close to and less thanc{\displaystyle c} .

It is a fact that limx→cf(x){\displaystyle \lim _{x\to c}f(x)} exists if and only if limx→c+f(x){\displaystyle \lim _{x\to c^{+}}f(x)} and limx→c−f(x){\displaystyle \lim _{x\to c^{-}}f(x)} exist and are equal to each other. In this case, limx→cf(x){\displaystyle \lim _{x\to c}f(x)} will be equal to the same number.

In our example, one limit does not even exist. Thus limx→2x−2{\displaystyle \lim _{x\to 2}{\sqrt {x-2}}} does not exist either.